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by Michael Tortorella
Reliability, Maintainability, and Supportability: Best Practices for Systems Engineers
Cover
Title page
Foreword
PURPOSE AND RATIONALE
GOALS
ORGANIZATION OF THIS BOOK
Acknowledgments
Part I: Reliability Engineering
1 Systems Engineering and the Sustainability Disciplines
1.1 PURPOSE OF THIS BOOK
1.2 GOALS
1.3 SCOPE
1.4 AUDIENCE
1.5 GETTING STARTED
1.6 KEY SUCCESS FACTORS FOR SYSTEMS ENGINEERS IN RELIABILITY, MAINTAINABILITY, AND SUPPORTABILITY ENGINEERING
1.7 ORGANIZING A COURSE USING THIS BOOK
1.8 CHAPTER SUMMARY
REFERENCES
2 Reliability Requirements
2.1 WHAT TO EXPECT FROM THIS CHAPTER
2.2 RELIABILITY FOR SYSTEMS ENGINEERS
2.3 RELIABILITY, MAINTAINABILITY, AND SUPPORTABILITY ARE MUTUALLY REINFORCING
2.4 THE STRUCTURE OF RELIABILITY REQUIREMENTS
2.5 EXAMPLES OF RELIABILITY REQUIREMENTS
2.6 INTERPRETATION OF RELIABILITY REQUIREMENTS
2.7 SOME ADDITIONAL FIGURES OF MERIT
2.8 CURRENT BEST PRACTICES IN DEVELOPING RELIABILITY REQUIREMENTS
2.9 CHAPTER SUMMARY
2.10 EXERCISES
REFERENCES
3 Reliability Modeling for Systems Engineers
3.1 WHAT TO EXPECT FROM THIS CHAPTER
3.2 INTRODUCTION
3.3 RELIABILITY EFFECTIVENESS CRITERIA AND FIGURES OF MERIT FOR NONMAINTAINED UNITS
3.4 ENSEMBLES OF NONMAINTAINED COMPONENTS
3.5 RELIABILITY MODELING BEST PRACTICES FOR SYSTEMS ENGINEERS
3.6 CHAPTER SUMMARY
3.7 EXERCISES
REFERENCES
4 Reliability Modeling for Systems Engineers
4.1 WHAT TO EXPECT FROM THIS CHAPTER
4.2 INTRODUCTION
4.3 RELIABILITY EFFECTIVENESS CRITERIA AND FIGURES OF MERIT FOR MAINTAINED SYSTEMS
4.4 MAINTAINED SYSTEM RELIABILITY MODELS
4.5 STABILITY OF RELIABILITY MODELS
4.6 SOFTWARE RESOURCES
4.7 RELIABILITY MODELING BEST PRACTICES FOR SYSTEMS ENGINEERS
4.8 CHAPTER SUMMARY
4.9 EXERCISES
REFERENCES
5 Comparing Predicted and Realized Reliability with Requirements
5.1 WHAT TO EXPECT FROM THIS CHAPTER
5.2 INTRODUCTION
5.3 EFFECTIVENESS CRITERIA, FIGURES OF MERIT, METRICS, AND PREDICTIONS
5.4 STATISTICAL COMPARISON OVERVIEW
5.5 STATISTICAL COMPARISON TECHNIQUES
5.6 FAILURE REPORTING AND CORRECTIVE ACTION SYSTEM
5.7 RELIABILITY TESTING
5.8 BEST PRACTICES IN RELIABILITY REQUIREMENTS COMPARISONS
5.9 CHAPTER SUMMARY
5.10 EXERCISES
REFERENCES
6 Design for Reliability
6.1 WHAT TO EXPECT FROM THIS CHAPTER
6.2 INTRODUCTION
6.3 TECHNIQUES FOR RELIABILITY ASSESSMENT
6.4 THE DESIGN FOR RELIABILITY PROCESS
6.5 HARDWARE DESIGN FOR RELIABILITY
6.6 QUALITATIVE DESIGN FOR RELIABILITY TECHNIQUES
6.7 DESIGN FOR RELIABILITY FOR SOFTWARE PRODUCTS
6.8 ROBUST DESIGN
6.9 DESIGN FOR RELIABILITY BEST PRACTICES FOR SYSTEMS ENGINEERS
6.10 SOFTWARE RESOURCES
6.11 CHAPTER SUMMARY
6.12 EXERCISES
REFERENCES
7 Reliability Engineering for High-Consequence Systems
7.1 WHAT TO EXPECT FROM THIS CHAPTER
7.2 DEFINITION AND EXAMPLES OF HIGH-CONSEQUENCE SYSTEMS
7.3 RELIABILITY REQUIREMENTS FOR HIGH-CONSEQUENCE SYSTEMS
7.4 STRATEGIES FOR MEETING RELIABILITY REQUIREMENTS IN HIGH-CONSEQUENCE SYSTEMS
7.5 CURRENT BEST PRACTICES IN RELIABILITY ENGINEERING FOR HIGH-CONSEQUENCE SYSTEMS
7.6 CHAPTER SUMMARY
7.7 EXERCISES
REFERENCES
8 Reliability Engineering for Services
8.1 WHAT TO EXPECT FROM THIS CHAPTER
8.2 INTRODUCTION
8.3 SERVICE FUNCTIONAL DECOMPOSITION
8.4 SERVICE FAILURE MODES AND FAILURE MECHANISMS
8.5 SERVICE RELIABILITY REQUIREMENTS
8.6 SERVICE-LEVEL AGREEMENTS
8.7 SDI RELIABILITY REQUIREMENTS
8.8 DESIGN FOR RELIABILITY TECHNIQUES FOR SERVICES
8.9 CURRENT BEST PRACTICES IN SERVICE RELIABILITY ENGINEERING
8.10 CHAPTER SUMMARY
8.11 EXERCISES
REFERENCES
9 Reliability Engineering for the Software Component of Systems and Services
9.1 WHAT TO EXPECT FROM THIS CHAPTER
9.2 INTRODUCTION
9.3 RELIABILITY REQUIREMENTS FOR THE SOFTWARE COMPONENT OF SYSTEMS AND SERVICES
9.4 RELIABILITY MODELING FOR SOFTWARE
9.5 SOFTWARE FAILURE MODES AND FAILURE MECHANISMS
9.6 DESIGN FOR RELIABILITY IN SOFTWARE
9.7 CURRENT BEST PRACTICES IN RELIABILITY ENGINEERING FOR SOFTWARE
9.8 CHAPTER SUMMARY
9.9 EXERCISES
REFERENCES
Part II: Maintainability Engineering
10 Maintainability Requirements
10.1 WHAT TO EXPECT FROM THIS CHAPTER
10.2 MAINTAINABILITY FOR SYSTEMS ENGINEERS
10.3 MAINTAINABILITY EFFECTIVENESS CRITERIA AND FIGURES OF MERIT
10.4 EXAMPLES OF MAINTAINABILITY REQUIREMENTS
10.5 MAINTAINABILITY MODELING
10.6 INTERPRETING AND VERIFYING MAINTAINABILITY REQUIREMENTS
10.7 MAINTAINABILITY ENGINEERING FOR HIGH-CONSEQUENCE SYSTEMS
10.8 CURRENT BEST PRACTICES IN MAINTAINABILITY REQUIREMENTS DEVELOPMENT
10.9 CHAPTER SUMMARY
10.10 EXERCISES
REFERENCES
11 Design for Maintainability
11.1 WHAT TO EXPECT FROM THIS CHAPTER
11.2 SYSTEM OR SERVICE MAINTENANCE CONCEPT
11.3 MAINTAINABILITY ASSESSMENT
11.4 DESIGN FOR MAINTAINABILITY TECHNIQUES
11.5 CURRENT BEST PRACTICES IN DESIGN FOR MAINTAINABILITY
11.6 CHAPTER SUMMARY
11.7 EXERCISES
REFERENCES
Part III: Supportability Engineering
12 Support Requirements
12.1 WHAT TO EXPECT FROM THIS CHAPTER
12.2 SUPPORTABILITY FOR SYSTEMS ENGINEERS
12.3 SYSTEM OR SERVICE SUPPORT CONCEPT
12.4 SUPPORT EFFECTIVENESS CRITERIA AND FIGURES OF MERIT
12.5 EXAMPLES OF SUPPORT REQUIREMENTS
12.6 INTERPRETING AND VERIFYING SUPPORT REQUIREMENTS
12.7 SUPPORTABILITY ENGINEERING FOR HIGH-CONSEQUENCE SYSTEMS
12.8 CURRENT BEST PRACTICES IN SUPPORT REQUIREMENTS DEVELOPMENT
12.9 CHAPTER SUMMARY
12.10 EXERCISES
REFERENCES
13 Design for Supportability
13.1 WHAT TO EXPECT FROM THIS CHAPTER
13.2 SUPPORTABILITY ASSESSMENT
13.3 IMPLEMENTATION OF FACTORS PROMOTING SUPPORTABILITY
13.4 QUANTITATIVE DESIGN FOR SUPPORTABILITY TECHNIQUES
13.5 CURRENT BEST PRACTICES IN DESIGN FOR SUPPORTABILITY
13.6 CHAPTER SUMMARY
13.7 EXERCISES
REFERENCES
Index
Wiley Series in Systems Engineering and Management
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Wiley Series in Systems Engineering and Management
Index
accelerated life model
differential
strong
weak
accelerated life test
acceleration transform
accuracy
acquisition cost
activation energy
activity network
age
aggregation
aging
alternating renewal process
AMSAA model
architecture
Arrhenius relationship
asymptotic failure rate
attribute requirements
availability
achieved
asymptotic
asymptotic average
inherent
operational
transient
bad-as-old
ball bearings
bias
binomial
birth-and-death process
brink-of-failure state
buffer overflow
Burke’s theorem
business continuity
calendar time
capacitor
bypass
capacity
link
census
central limit theorem
certification
circuit pack
circuit simulation
circuit switch
clumsy repairman
code
error-correcting
error-detecting
common cause
competing risk
component reliability estimates
concept FMEA
conditional independence
confidence interval
confidence level
confidence limit
congestion
connectedness
consumer’s risk
continual improvement
control chart
control factor
convolution
corrective action
cost
appraisal
external failure
prevention
count description
crack growth
critical path method
criticality
cumulative distribution function
cumulative hazard function
customer–supplier model
customer–supplier relationship
cut
minimal
set
cycle time
data
reliability
decimal places
decision procedure
degradation analysis
degrees of freedom
delay time
administrative
inefficiency
logistic
delivery function
Deming cycle
demography
density
dependability
design choice
design FMEA
design patterns
design review
development release
diagram
control flow
data flow
disaster recovery
discretionary variable
distributed systems
distribution
exponential
gamma
Gaussian
see
distribution, normal
limiting
lognormal
normal
standard normal
Student’s
t
truncated normal
uniform
Weibull
documentation
downtime
DPM
Drenick’s theorem
drift
Duane plot
durability
duty cycle
early life failure
effectiveness criteria
maintainability
reliability
support
electromigration
electronic switching
empirical distribution
end-of-life failure
enterprise management software
ergonomics
error
Type
Type
exception handling
facility layout
facility location
failover time
failures
acute
cause
chronic
hard
intensity
isolation
mechanism
mode
rate
service
soft
software
time
fault location
fault tolerance
fault tree analysis
field-replaceable unit
figure of merit
maintainability
reliability
support
fishbone diagram
force of mortality
human
forward recurrence time
FRACAS
functional decomposition
service
system
good as new
graph
directed
labeled
random
Grigelionis’s theorem
HAST
hazard rate
high-consequence system
histogram
hot carrier damage
House of Quality
independence
infrastructure
critical
service delivery
instantaneous repair
integral equation
intensity
invariance principle
invariance property
inventory management
inventory optimization
Ishikawa diagram
joint distribution
Kano Analysis
Kaplan–Meyer method
knowledge
quality of
latent defect
level of repair analysis
life distribution
life testing
lifetime
line-replaceable unit
load-service curve
logistics
longevity
machine servicing model
maintainability
services
maintainability block diagram
maintainable system
maintained system
maintenance
condition-based
corrective
depot-level
facility
functional decomposition
intermediate
level of
off-line
on-line
predictive
preventive
reliability-centered
task analysis
management by fact
manufacturing defects
Markov chain
Markov process
mean outage time
mean time between outages
measures of effectiveness
mechanical wear
median
memory leak
memoryless property
metric
mid-life failure
minimal cut
minimal path
mission success probability
mode
model
stability
stress-strength
modification request
network
directed
flow
resiliency
robustness
noise
noise factor
normal approximation
numerical methods
1 – 10 – 100 rule
operating interval
operating time
operational profile
operational reliability
operational time
optimization
order statistic
outage
outage interval
outage time
oxide breakdown
parallel system
Pareto chart
parity checking
path
minimal
set
percentile
performance
physical design
point process
Poisson process
compound
homogeneous
nonhomogeneous
pool
power dissipation
precedence diagram
precision
preventive action
preventive maintenance
see
maintenance, preventive
printed circuit board
printed wiring board
process capability
process flow diagram
process quality
producer’s risk
profitability
proportional hazards
PSTN
qualification
Quality Function Deployment
quality of information
quality of knowledge
see
knowledge, quality of
quantitative modeling
queueing
random sample
random variable
continuum
discrete
redundancy
active
cold standby
hot standby
k
-out-of-
n
passive
regression testing
reliability
assessment
block diagram
budget
component
data
design for
economics
function
growth
importance
improvement strategy
logic
mathematical theory of
modeling
modeling software
network
network element
physics
prediction
process
service
software
testing
RELIC
renewal
renewal process
repair
execution of
preparation for
requirement
attribute
functional
maintainability
performance
physical
reliability
safety
service reliability
support
user-oriented
violation of
restore
reuse
software
revival
revival process
risk management
reliability
robust design
root cause
root cause analysis
rot
routing
routing matrix
sampling error
scale factor
schematic capture
security
separate maintenance model
serial number
series system
service
accessibility
continuity
delivery infrastructure
fulfillment
functional decomposition
level agreement
life
maintenance concept
on-demand
standing
release
session initiation protocol
7-step quality improvement process
shared resources
simulation
single point of failure
six sigma
software engineering
software reliability engineering
sojourn time
solder attachment
spares pool
special cause
specification limits
SPICE
staff sizing
stakeholders
standard deviation
standard error
standards
state diagram
statistic
statistical fluctuation
statistical significance
steady state
stochastic flow network
stochastic network flow model
stochastic Petri net
stochastic process
stochastically independent
stockout
stockout probability
strength density
stress density
stress relaxation
stress–strength model
stress–strength relationship
structure function
superposition
support concept
support time
supportability
off-line
on-line
survival probability
survivor function
sustainability
system
formal
functional decomposition,
high-consequence
history diagram
maintenance concept
nonnmaintained
reliability budget
see
reliability budget
reliability process
see
reliability process
support concept
t
-distribution approximation
test
built-in
test, analyze, and fix
thermal analysis
thermal impedance
throughput
time
calendar
between failures
mission
operational
time-and-motion study
time-description
top event
total-cost-of-ownership
traffic equation
training
transaction
transition matrix
transportation
unreliable switch
utilization
vacuum tube
variance
Voice over Internet Protocol
warranty
wearout
failure modes
mechanical
mechanism
statistical
workflow management
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